Display and information-printed matter

ABSTRACT

A display includes a substrate with a light-transmitting property, a relief structure-forming layer disposed on at least one surface of the substrate and including a relief-structured region on a surface thereof opposite to its surface in contact with the substrate, a light-reflecting layer disposed on the surface of the relief structure-forming layer including the relief-structured region, and a printed layer formed on a surface of the substrate opposite to the surface on which the relief structure-forming layer is disposed, or between the relief structure-forming layer and the light-reflecting layer, or on a side of the light-reflecting layer opposite to its surface in contact with the relief structure-forming layer. The relief-structured region is constituted by recessed or protruding portions arranged two-dimensionally, has low reflectivity and low diffusibility under a normal illumination condition, and exhibits a diffracted light-emitting property under a specific condition.

CROSS REFERENCE TO RELATED APPLICATIONS

This is a Continuation Application of PCT Application No.PCT/JP2007/072134, filed Nov. 14, 2007, which was published under PCTArticle 21(2) in Japanese.

This application is based upon and claims the benefit of priority fromprior Japanese Patent Applications No. 2007-138808, filed May 25, 2007;and No. 2007-152730, filed Jun. 8, 2007, the entire contents of both ofwhich are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a forgery prevention technique.

2. Description of the Related Art

Authentication articles such as cash cards, credit cards and passportsand securities such as gift certificates and stock certificates aredesired to be difficult of forgery. For this reason, a label which isdifficult of forgery or imitation and which makes it easy to distinguisha genuine article from a forged article or an imitated article hasconventionally been attached to such an article in order to suppress theforgery.

Further, in recent years, circulation of forged articles is regarded asa problem also for articles other than the authentication articles andsecurities. For this reason, opportunities have been increasing to applyto such articles the forgery prevention technique mentioned for theauthentication articles and the securities.

Patent document 1 describes a display in which multiple pixels arearranged. In this display, each pixel includes a relief-type diffractiongrating in which grooves are arranged.

This display displays an image by utilizing diffracted light, and henceit is impossible to forge the display using the printing technique orelectrophotographic technique. Accordingly, if this display is attachedto an article as a label for authentication, seeing the image displayedon the label makes it possible to confirm that the article is genuine.Therefore, an article to which this label is attached is hardly forgedas compared with an article to which this label is not attached.

The above-mentioned relief-type diffraction grating, however, can beformed with comparative ease if a device such as a laser is available.Further, in the above display, although a change in the display image iscaused by changing an angle of incidence of the illumination light, anobservation angle or an orientation of the display, the change is not sorich in variety. Therefore, with the development of the technology, theforgery prevention effect of this display is becoming lower.Incidentally, difficulty of forgery or imitation, or ease in distinctionof a genuine article from a forged or imitated article is called here aforgery prevention effect.

Patent document 1: Jpn. Pat. Appln. KOKAI Publication No. 2-72320

BRIEF SUMMARY OF THE INVENTION Problem to be Solved by Invention

An object of the present invention is to realize a higher forgeryprevention effect.

Means for Solving Problem

According to a first aspect of the present invention, there is provideda display characterized by comprising a substrate with alight-transmitting property, a relief structure-forming layer disposedon at least one surface of the substrate and including arelief-structured region on a surface thereof opposite to its surface incontact with the substrate, a light-reflecting layer disposed on thesurface of the relief structure-forming layer including therelief-structured region, and a printed layer formed on a surface of thesubstrate opposite to the surface on which the relief structure-forminglayer is disposed, or between the relief structure-forming layer and thelight-reflecting layer, or on a side of the light-reflecting layeropposite to its surface in contact with the relief structure-forminglayer, wherein the relief-structured region is constituted by recessedor protruding portions arranged two-dimensionally, has low reflectivityand low diffusibility under a normal illumination condition, andexhibits a diffracted light-emitting property under a specificcondition.

According to a second aspect of the present invention, there is providedan information-printed matter characterized by comprising the displayaccording to the first aspect, and a printed matter substrate supportingit.

Advantageous Effect of Invention

According to the present invention, a higher forgery prevention effectcan be realized.

DETAILED DESCRIPTION OF THE INVENTION

Embodiments of the present invention will be described below in detailwith reference to the accompanying drawings. Incidentally, in thedrawings, constituent elements exhibiting the same or similar functionare denoted by the identical reference symbols, and a duplicatedescription will be omitted.

FIG. 1 is a plan view schematically showing a display according to afirst embodiment of the present invention. FIG. 2 is a cross-sectionalview of the display shown in FIG. 1 taken along the line X-X′.

This display 1 includes a layered product of a substrate 5 with alight-transmitting property, a relief structure-forming layer 2 disposedon one surface of the substrate 5 and including a relief-structuredregion 6 on a surface thereof opposite to its surface in contact withthe substrate 5, a light-reflecting layer 3 disposed on the surface ofthe relief structure-forming layer 2 including the relief-structuredregion 6, and a printed layer 4 disposed on the other surface of thesubstrate 5. In the example shown in FIG. 2, the side on the printedlayer 4 is the front side (observer's side), while the side on thelight-reflecting layer 3 is the back side.

The substrate 5 with a light-transmitting property is a film or sheetmade of a resin having a light-transmitting property such aspolyethylene terephthalate (PET), polycarbonate (PC) ortriacetylcellulose. As the material of the substrate 5, inorganicmaterial such as glass may also be used. The substrate 5 may have amonolayer structure or multilayered structure. The substrate 5 may besubjected to a treatment such as antireflection treatment,low-reflection treatment, hard-coating treatment, antistatic treatmentor soil-resistant treatment.

As the material of the relief structure-forming layer 2, for example, aresin having a light-transmitting property can be used. For example, inthe case where a thermoplastic resin, a thermosetting resin or aphoto-setting resin is used, the relief structure-forming layer 2 can beformed easily by a transfer using a master to have a surface includingthe relief-structured region 6 constituted by the recessed or protrudingportions. The materials of the substrate 5 and the reliefstructure-forming layer 2 may be the same or different.

As the light-reflecting layer 3, for example, a metal layer made of ametal material such as aluminum, silver and an alloy thereof can beused. Alternatively, as the light-reflecting layer 3, a dielectric layerhaving a refractive index different from that of the reliefstructure-forming layer 2 may be used. Alternatively, as thelight-reflecting layer 3, a layered product of dielectric layers inwhich adjacent dielectric layers have different refractive indices,i.e., multilayered dielectric film may be used. It is preferable thatthe dielectric layer of the multilayered dielectric film in contact withthe relief structure-forming layer 2 has a refractive index differentfrom the refractive index of the relief structure-forming layer 2.

The metal layer, the dielectric layer and the multilayered dielectricfilm can be formed using a thin-film formation technique such asevaporation or sputtering. Further, it is possible to spatiallydistribute the region in which the light-reflecting layer 3 is presentso as to display a pattern using the distribution of thelight-reflecting layer 3, for example, using the contours of the regionin which the light-reflecting layer 3 is present.

The printed layer 4 displays an image such as pattern, character orsymbol, and various inks such as offset inks, letterpress inks orgravure inks can be used depending on the method for printing theprinted layer 4. The ink used for the printing can be classified basedon a classification by composition such as resin-type ink, oil-based inkand water-based ink or a classification by drying process such asoxidative polymerization-type ink, penetration dry-type ink, evaporationdry-type ink and ultraviolet-curing ink, and is appropriately selectedaccording to the type of the substrate and the printing method. Further,it is a commonly used technique for forming a printed layer that a tonerobtained by attaching coloring particles such as graphite or pigment toplastic particles having a property of electrification is transferredonto a substrate such as paper by utilizing static electricity and thenfixed by heating.

In FIG. 2, the printed layer 4 is depicted as a layer which is formed onthe surface of the substrate 5 opposite to the surface provided with therelief structure-forming layer 2 and is the nearest with respect to anobserver. The printed layer 4 may be formed between the reliefstructure-forming layer 2 and the light-reflecting layer 3 or on theside of the light-reflecting layer 3 opposite to the surface in contactwith the relief structure-forming layer 2.

FIGS. 3 and 4 are sectional views each showing, in an enlarging manner,an example of a display structure that can be employed in the presentinvention.

As in the sectional view shown in FIG. 3, in the case where the printedlayer 4 is placed between the relief structure-forming layer 2 and thelight-reflecting layer 3, it is preferable that the printed layer 4 isformed using a material having a refractive index close to that of thematerial of the relief structure-forming layer 2. This makes therecessed or protruding portions in the relief-structured region 6flattened at the position where the printed layer 4 is formed, and it isthus visually perceived as if the recessed or protruding portions areabsent. Accordingly, if a solid plate having the relief-structuredregion 6 on the entire surface of the substrate 5 is formed, even in thecase of a small-volume production, etc., a display having a pattern canbe easily manufactured by forming the printed layer 4 between the reliefstructure-forming layer 2 (the solid plate) and the light-reflectinglayer 3 without using a master for forming the display 1.

As in the sectional view shown in FIG. 4, in the case where the printedlayer 4 is provided on the side of the light-reflecting layer 3 oppositeto the surface in contact with the relief structure-forming layer 2, itis necessary to bring about such a state that an observer can observe,for example, by providing the light-reflecting layer 3 not entirely butpartially on the surface.

The display 1 may be further provided with the adhesive layer 7 on theside of the light-reflecting layer 3 opposite to its surface in contactwith the relief structure-forming layer 2. When the adhesive layer 7 isprovided, the surface of the light-reflecting layer 3 is not exposed,and thus replication of the recessed or protruding portions is difficulteven in the case where the surface shape of the light-reflecting layer 3is almost the same as the shape of the interface between the reliefstructure-forming layer 2 and the light-reflecting layer 3. In the casewhere the side of the relief structure-forming layer 2 is the back side,while the side of the light-reflecting layer 3 is the front(observation) side, the adhesive layer is formed on the relief structurelayer 2. In this case, the relief-structured region is included not inthe interface between the relief structure layer 2 and thelight-reflecting layer 3 but in the interface between thelight-reflecting layer 3 and the external environment.

FIG. 5 is a perspective view showing, in an enlarging manner, an exampleof a structure that can be employed in the relief-structured region 6 ofthe display shown in FIGS. 1 and 2.

The relief-structured region 6 shown in FIG. 5 is provided with theprotruding portions 8. Although the relief-structured region 6 isconstituted only by the protruding portions 8 here, this is merely anexample. In the present invention, the relief-structured region 6 can beformed using recessed portions.

Next, the special visual effect of the display 1 originated from therelief structure-forming layer 2 be described.

In the case where center-to-center distances of the adjacent recessed orprotruding portions of the relief structure-forming layer(relief-structured region 6) have a constant periodicity as shown inFIG. 5, when the relief structure-forming layer is illuminated, therelief structure-forming layer emits diffracted light in a specificdirection with respect to the direction of illumination light asincident light.

1st-order diffracted light is the most representative diffracted light.An angle of emergence β of 1st-order diffracted light can be calculatedusing the following equation (1).

d=mλ/(sin α−sin β)  (1)

In this formula (1), d represents a center-to-center distance of therecessed or protruding portions, and λ represents a wavelength of theincident light and the diffracted light. Further, α represents the angleof emergence of the 0-order diffracted light, i.e., the transmittedlight or the regular reflected light.

As is evident from the formula (1), the angle of emergence β of the1st-order diffracted light changes according to the wavelength λ. Thatis, the relief structure-forming layer has a function as a spectroscope.Accordingly, in the case where the illumination light is white light,when the observation angle for the relief structure-forming layer ischanged, the color perceived by the observer will be changed.

Further, the color perceived by the observer under a certain observationcondition changes according to the grating constant d. As an example, itis assumed that the relief structure-forming layer emits 1st-orderdiffracted light in the normal direction thereof. That is, it is assumedthat the angle of emergence β of the 1st-order diffracted light is 0°.Further, it is assumed that the observer perceives this 1st-orderdiffracted light. When it is assumed that the angle of emergence of the0-order diffracted light at this time is α_(N), the formula (1) can besimplified to the following formula (2).

d=λ/sin α_(N)  (2)

As is evident from the formula (2), in order to allow the observer toperceive a specific color, it suffices that a wavelength λ correspondingto the color, an incident angle |α_(N)| of the illumination light, and acenter-to-center distance d are set to satisfy the relationship shown bythe formula (2).

In the present invention, the relief-structured region is constituted bythe recessed or protruding portions arranged two-dimensionally, has lowreflectivity and low diffusibility under a normal illuminationcondition, and exhibits a diffracted light-emitting property under aspecific condition. Since the relief-structured region has lowreflectivity and low diffusibility under the normal illuminationcondition, a color with low degrees of lightness and chromaticness suchas black and dark gray is perceived under the normal illuminationcondition. On the other hand, since it has the diffracted light-emittingproperty under the specific condition, it has the diffractedlight-emitting property when observed under the specific condition.

Here, “normal illumination condition” refers to a condition in whichlight from illumination light enters a surface of a substrate almostperpendicularly under illumination light, for example, that from afluorescent lamp and an observer visually observes the display in anordinary indoor environment, or a condition in which light fromillumination light enters a surface of a substrate almostperpendicularly under illumination light such as sunlight and anobserver visually observes the display in an outdoor environment. Here,“normal illumination light” refers to the illumination light in thenormal illumination condition.

On the other hand, “specific condition” means a condition in which lightfrom illumination light enters a surface of a display almosthorizontally, i.e., at an acute angle, and an observer visually observesthe display.

Thus, when the display is observed in the normal direction thereof, therelief structure-forming layer is seen black. Here, “black” means thatthe reflectance for any of the light components within a wavelengthrange of 400 nm to 700 nm is 25% or less when the display 1 isirradiated with light from the normal direction and the intensity of theregular reflected light is measured. Thus, the relief structure-forminglayer is seen as if it is a black printed layer. Dark gray with lowdegrees of lightness and chroma is perceived when the reflectance isabout 25% or less, while a sufficient antireflection effect is achievedand thus black is perceived when the reflectance is 10% or less,although it varies depending on the environment of observation andindividual differences.

In the case where the angle of emergence of the 1st-order diffractedlight from the relief structure-forming layer falls within a range of−90° to 90°, if the angle formed by the normal to the display and theobservation direction is set appropriately, the observer can perceivethe 1st-order diffracted light from the relief structure-forming layer.Thus, in this case, it is possible to check with eyes that the reliefstructure-forming layer is different from a black printed layer.

That is, the relief structure-forming layer including therelief-structured region can greatly decrease the reflectance forregular reflected light with respect to incident light and can allowvisible light to be emitted as reflection-diffracted light by theperiodicity of the arrangement of the recessed or protruding portions ina specific direction depending on the incident angle of the incidentlight. In contrast, the printed layer 4 formed using ink or tonerexhibits a color, i.e., hue, lightness and chroma unique to the ink ortoner, and the incident angle of the incident light does not greatlychanges the color. Therefore, under most observation conditions, therelief structure-forming layer is seen black while the normal reflectedlight from the printed layer can be observed, and hence a high-contrastimage can be displayed.

On the other hand, since diffracted light can be observed under theaforementioned condition in which the 1st-order diffracted light can beobserved, it is possible to impart a unique visual effect that an imageseen black under a normal condition is suddenly seen lucently whenchanging the observation angle.

Therefore, when it is used in an information-printed matter for forgeryprevention including the display and a printed matter substratesupporting this, a high forgery prevention effect can be achieved.

In the display, the relief-structured region coexists with the region inwhich the printed layer is formed. Both display images which an observerperceives. Under the normal illumination condition, therelief-structured region displays an image of black or dark gray, whilethe region of the printed layer displays an image of a color, i.e., hue,lightness and chroma unique to the ink or toner. When the observationcondition is changed, for example, by inclining display, diffractedlight is perceived for the relief-structured region, while the samecolor as that under the normal illumination condition is perceived forthe printed layer, and thus a difference in vision appears clearly.

Such an effect cannot be achieved only by a printed layer and cannot beachieved even by a combination of a printed layer and a diffractiongrating pattern. Since the aforementioned effect is achieved by thecombination of the relief structure-forming layer including therelief-structured region and the printed layer, a visual effect thatcannot be achieved by conventional displays is produced, and thus itbecomes possible to obtain the forgery prevention effect.

As the ink or toner for forming the printed layer, the one exhibitinglow reflectivity and low diffusibility for a predetermined illuminationlight is used preferably. In other words, it is preferable that thecolor of the ink or toner has almost the same hue, lightness and chromaas that of the black or dark gray displayed by the reliefstructure-forming layer including the relief-structured region. Thismakes it difficult to discern the difference of constructions becausealmost the same color is perceived for them under the normalillumination condition. Further in the case where the observationcondition is changed, for example, by inclining the display, thedifference of constructions can be discerned because the reliefstructure-forming layer emitting diffracted light exhibits a visualeffect different from that of the printed layer.

For example, it is possible to impart the effect that under the normalillumination condition, the region 9 painted over in solid black isperceived as merely a rectangle as shown in FIG. 6, while under aspecific condition, for example, under a condition that the display 1 isinclined, the rectangular region 9 is divided into a character portiondisplayed by the relief structure-forming layer including therelief-structured region 6 and a portion surrounded by the characterportion and displayed by the printed layer, and thus the informationthat cannot be recognized under the normal illumination condition can beobtained.

As the ink for printing, a functional ink capable of changing its coloraccording to the observation angle can be used. Examples of thefunctional ink capable of changing its color according to theobservation angle include so-called optical variable inks, color shiftinks and pearl inks.

The optical variable inks and the color shift inks have a function ofcolor change, for example, from red to green or from blue to violetaccording to the observation angle, while the pearl inks have a functionof displaying light pearl-like color at a specific angle. When such afunctional ink is used, both the relief structure-forming layer and theprinted layer can exhibit color change according to the observationangle. In the case where multiple regions of the display employ such astructure that causes color change, even for a person unaccustomed to aprocedure of descriminating between a genuine article and a non-genuinearticle by inclining the display, the color change can be perceivedeasily, and thus the descrimination between a genuine article and anon-genuine article can be performed with reliability. Particularly,when the angle at which the color change due to the functional inkoccurs and the angle at which the color change due to the reliefstructure-forming layer occurs are almost equal to each other, bothcolor changes can be observed simultaneously, and thus thedescrimination between a genuine article and a non-genuine article canbe performed with a higher degree of reliability.

Since the relief structure-forming layer including the relief-structuredregion according to the present invention has a function of switchingbetween a black or dark gray display and a display utilizing color ofdiffracted light depending on the observation angle, when a functionalink exhibiting the color change is used as the ink for forming theprinted layer, both the relief structure-forming layer and the printedlayer can exhibit color change according to the observation angle, andthus a higher forgery prevention effect can be obtained.

Particularly, when the angle at which the change between the black ordark gray display by the relief structure-forming layer including therelief-structured region and the display utilizing color of diffractedlight occurs is made equal to the angle at which the color of thefunctional ink changes, both change can be perceived simultaneously,thus a higher forgery prevention effect can be achieved as compared witha display in which only one of them is present, and the descriminationbetween a genuine article and a non-genuine article can be performedwith a higher degree of reliability. In this case, under the normalillumination condition, the character portion displayed by the reliefstructure-forming layer (relief-structured region 6) and the characterportion displayed by the printed layer 4 are perceived as differentcolors as shown in FIG. 8, while under the specific condition, forexample, under a condition that the display 1 is inclined, each of thecharacter portion displayed by the relief structure-forming layer(relief-structured region 6) and the character portion displayed by theprinted layer 4 changes to a different color.

As a printing technique exerting a forgery prevention effect, a latentimage pattern is known. A display image of the latent image patterncannot be recognized under a normal illumination condition, and theconcealed display image becomes recognizable, for example, when adisplay is inclined at a predetermined angle.

As the construction of the latent image pattern, generally employed isthe construction in which the concealed image 10 and the peripheralportion 11 are constituted by fine lines intersecting at right angles asshown in FIG. 10. The pitch of the fine lines is about 3 to 10 lines per1 mm. The image constituted as such is hard to distinguish the verticallines and the horizontal lines intersecting at right angles under thenormal illumination condition, thus is difficult of recognizing theimage (in FIG. 10, the pitch of the fine lines are depicted greater thanthat of the actual one, and thus the image is recognizable).

When such a latent image pattern is observed in a state inclined at apredetermined angle, the vertical lines of the concealed image 10 andthe horizontal lines of the peripheral portion 11 are seen to havedifferent pitches. This difference allows an observer to perceive theconcealed image.

Since the relief structure-forming layer according to the embodiment ofthe present invention has a function of switching between a black ordark gray display and a display and a display utilizing color ofdiffracted light depending on the observation angle, when a latent imagepattern is formed by the printed layer, the color change according tothe observation angle and the change of the displayed image according tothe observation angle caused by the latent image pattern can be mutuallycompatible, and thus a higher forgery prevention effect can be obtained.

Particularly, when the angle and the direction at which the changebetween the black or dark gray display by the relief structure-forminglayer including the rerief-structured region and the display utilizingcolor of diffracted light occurs are made equal to the angle and thedirection at which the concealed image by the latent image patternappears, both changes can be observed simultaneously, a higher forgeryprevention effect can be achieved as compared with the display in whichonly one of them is present, and the descrimination between a genuinearticle and a non-genuine article can be performed with a higher degreeof reliability. In this case, under the normal illumination condition,the latent image pattern (concealed image 10) cannot be recognized asshown in FIG. 10; and when the observation angle is changed, the latentimage pattern (concealed image 10) appears as shown in FIG. 11 and thediffracted light from the relief structure-forming layer including therelief-structured region can be observed.

It is preferable that a surface area of the single recessed orprotruding portion is equal to or greater than 1.5 times an occupiedarea necessary for placing the single recessed or protruding portion onthe surface of the relief structure-forming layer. When the surface areaof the single recessed or protruding portion is equal to or greater than1.5 times the occupied area, excellent low-reflectivity andlow-diffusibility can be obtained. That is, black is recognized whenobserved visually. On the other hand, the case where the surface area ofthe single recessed or protruding portion is less than 1.5 times theoccupied area is not preferable because the reflectance is high similarto the properties of a flat surface.

As the method of shaping the recessed or protruding portions formed onthe relief structure-forming layer, various methods such as radiationcure molding, extrusion molding and heat press molding can be utilized.Examples of a shape that can be employed for the recessed or protrudingportions formed on the relief structure-forming layer include a circularcone shape, a pyramid shape, an elliptic cone shape, a cylindricalcolumn or circular cylinder shape, a prism or rectangular cylindershape, a truncated circular cone shape, a truncated prism shape, atruncated elliptic cone shape, a shape obtained by joining a cylindricalcolumn or circular cylinder and a circular cone together, a shapeobtained by joining a prism or rectangular cylinder and a pyramidtogether, a semi-sphere shape, a semi-ellipse shape, a bullet shape anda bowl shape.

Particularly, it is preferable that the cross sections of the recessedor protruding portions formed on the relief structure-forming layer havea tapered shape. When the cross sections of the recessed or protrudingportions have a tapered shape, the property of demolding a resin from astamper made of metal is excellent, and thus a high degree of massproductivity can be achieved. Further, in the case where the crosssections of the recessed or protruding portions have a tapered shape,higher degrees of low-reflectivity and low-diffusibility can be achievedas compared with the case where the cross sections of the recessed orprotruding portions have a rectangular shape.

Here, a tapered shape refers to the case where a recessed or protrudingportion is formed such that a cross-sectional area thereof parallel witha surface of a substrate decreases from the base end toward the tip.

FIG. 12 is an enlarged cross-sectional view of a reliefstructure-forming layer 2 (relief-structured region 6) in which therecessed or protruding portions have a truncated shape.

Generally, in the case where the recessed or protruding portions haveone of a truncated circular cone shape, a truncated pyramid shape and atruncated elliptic cone shape, the flat surfaces 12 on the truncatedtops of the recessed or protruding portions increase the regularreflectance. However, when the width d1 of the flat surfaces 12 is set90 nm or less, the regular reflected component caused by the flatsurfaces can be decreased sufficiently, and thus black can be displayedon the relief structure-forming layer. That is, black can be displayedat almost the same degree as in the case where the width d1 of the flatsurfaces is 0 nm. Further, in the case where the width 12 of the flatsurfaces is 90 nm or less, if some errors occur in processing accuracy,the relief-structured region can be obtained to have desired opticalproperties, and thus processing such as electron bean drawing andetching and a volume production can be performed easily.

FIGS. 13 and 14 are plan views each schematically showing an example ofan arrangement pattern of the recessed or protruding portions that canbe employed in the relief structure-forming layer (relief-structuredregion 6).

In the relief structure-forming layer (relief-structured region 6) shownin FIG. 13, the recessed or protruding portions 13 are arranged in amatrix form at a predetermined center-to-center distance. This structureis comparatively easy to manufacture using a fine processing apparatussuch as an electron beam drawing apparatus or a stepper and alsocomparatively easy to precisely control the center-to-center distance ofthe recessed or protruding portions, etc.

In addition, in the structure of FIG. 13, the recessed or protrudingportions are arranged regularly. Accordingly, when the center-to-centerdistance of the recessed or protruding portions 13 is set 200 nm ormore, it is possible to allow the relief-structured region 6 to emitdiffracted light. In this case, it is possible to visually confirm thatthe relief-structured region 6 is different from a black printed layer.

Further, when the center-to-center distance of the recessed orprotruding portions 13 is set less than 200 nm, emission of diffractedlight from the relief-structured region 6 can be prevented. In thiscase, in terms of the observed color, it becomes difficult to visuallyconfirm that the relief-structured region 6 is different from a blackprinted layer.

In the relief structure-forming layer (relief-structured region 6) shownin FIG. 14, the recessed or protruding portions 13 are arranged in ahoneycomb form at a predetermined center-to-center distance. Thisstructure can make the area occupied by the recessed or protrudingportions 13 small, and thus reflection of light can be prevented moreefficiently.

It should be noted that in the present invention, the arrangementpattern of the recessed or protruding portions is not limited to theabove described matrix or honeycomb form. It may be an arrangementpattern having other periodicities such as a rectangular lattice.

When the center-to-center distance of the adjacent recessed orprotruding portions of the relief structure-forming layer including therelief-structured region is 400 nm or less, it is possible to preventany diffracted light within a wavelength range of 400 to 700 nm, whichis the visible light range, from being emitted in the normal directionregardless of the incident angle of the illumination light. According tothe equation (2), the light of 400 nm is barely able to travel in thenormal direction when illuminated at 89°. Thus, under any illuminationcondition, the recessed or protruding portions cannot emit diffractedlight toward the front at sufficient intensity within substantially thewhole visible range of wavelength. That is, diffracted light is emittedat an angle greatly different from the normal direction, and thusdiffracted light can be observed only when it is greatly inclined withrespect to the normal direction.

Here, the center-to-center distance means the distance d2 between thecentral axes of the adjacent recessed or protruding portions shown inFIG. 12.

When the center-to-center distance of the recessed or protrudingportions is 250 nm or more and 300 nm or less, as for the visiblewavelength range of 400 to 700 nm, diffracted light corresponding to atleast the red component cannot be observed on the reliefstructure-forming layer. That is, although the relief structure-forminglayer does not emit diffracted light in the direction normal to thedisplay and emits diffracted light at an angle greatly different fromthe normal direction similar to the case where the center-to-centerdistance is 400 nm or less, no diffraction occurs at the visible lightwavelength corresponding to red and diffraction occurs only at thevisible light wavelength corresponding to blue and green, and thus it ispossible to display only the color that does not change between therainbow colors as a conventional hologram but is similar to blue andgreen.

Preferably, the height of the recessed or protruding portions in thedirection perpendicular to the surface of the substrate is 200 nm ormore and 600 nm or less. In the case where the height is less than 200nm, the reflectance increases as the properties of a flat surface, andthus it is impossible to impart sufficient low-reflectivity andlow-diffusibility. In the case where the height is more than 600 nm,replicating the relief structure-forming layer is difficult.

Here, the height of the recessed or protruding portions means the heighth1 of the recessed or protruding portions shown in FIG. 12.

The relief structure-forming layer including the relief-structuredregion can make the recessed or protruding portions give different phaseretardations to P-polarized light and S-polarized light, and thus ispossible to exhibit a polarizing property. When the diffracted lightemitted by the relief structure-forming layer having a polarizingproperty is observed through a polarizing plate, it is possible to seethat switching between a state where diffracted light is visible and astate where no diffracted light is visible occurs according to thepolarizing direction of the polarizing plate. The polarizing property ofthe relief structure-forming layer allows the descrimination between agenuine article and a non-genuine article using a polarizing plate, andthus the forgery prevention effect is further enhanced.

The relief structure-forming layer may be provided with a diffractiongrating pattern region adjacent to the relief-structured region. Whenthe diffraction grating pattern region is provided, a higher forgeryprevention effect can be obtained. A diffraction grating pattern displaywhich is used with and adhered to a security emits diffracted light dueto a light-reflecting layer made of, for example, aluminum and adiffraction grating structure, and thus has an effect of iridescence.Under such an observation condition that no diffracted light is emittedtoward the observer, only a metallic luster (for example, gold orsilver) of the light-reflecting layer is perceived. Since the displayincluding the relief-structured region and the diffraction gratingpattern region can display black or dark gray that a conventionaldiffraction grating pattern display cannot display, a visual effectdifferent from that of a conventional diffraction pattern display can beobtained.

In addition, since the relief-structured region and the diffractiongrating pattern region are relief structure having a concavo-convexcross section, it is possible to provide a single master with bothstructures so as to form the relief structure-forming layer includingthe relief-structured region and the diffraction grating pattern regionon the substrate in a single step.

FIG. 15 is a plan view schematically showing an example of aninformation-printed matter 100 including the display 1 according to thepresent invention.

Although an IC (integrated circuit) card is illustrated here as aninformation-printed matter, the information-printed matter including thedisplay 1 is not limited to this. For example, the information printedmatter including the display 1 may be other cards such as a wirelesscard, a magnetic card, an ID (identification) card, and the like.

In the IC card (information-printed matter 100) shown in FIG. 15,multiple forgery prevention measures including a function of the display1 which allows for visual verification of genuineness and a function ofthe IC 20 in which encrypted information is recorded and which allowsfor non-visual verification of genuineness, and thus the forgeryprevention performance of the information-printed matter is enhanced.

Further, the information-printed matter 100 includes a second printedlayer 30 in addition to the display 1, and visual comparison between thesecond printed layer 30 and the display 1 is easy. Therefore, an articlewhose genuineness is uncertain can be easily descriminated between agenuine article and a non-genuine article as compared with the casewhere the information-printed matter 100 does not include the secondprinted layer 30.

That is, although it is preferable that the second printed layer 30 hasthe same function as that of the printed layer according to the presentinvention, the printed layer used in the display 1 and the secondprinted layer 30 do not necessarily require the same function.

The information-printed matter including the display 1 may be a securitysuch as a gift certificate, a stock certificate and a check.Alternatively, the information-printed matter 100 including the display1 may be a tag to be attached to an article, which is to be confirmed asa genuine article. Alternatively, the information-printed matter 100including the display 1 may be a package or a part thereof foraccommodating an article to be confirmed as a genuine article.

Although in the printed matter 100 (IC card) shown in FIG. 15, thedisplay 1 is adhered to the printed matter substrate 50, the display 1can be supported by the substrate by other methods. For example, whenpaper is used as the printed matter substrate 50, the display 1 may beembedded in the paper, and the paper may be opened at a positioncorresponding to the display 1.

The display 1 may be used for a purpose other than forgery prevention.For example, the display 1 can also be utilized as a toy, a learningmaterial, a decorative article, etc.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING

FIG. 1 is a plan view schematically showing a display according to afirst embodiment of the present invention;

FIG. 2 is a cross-sectional view of the display shown in FIG. 1 takenalong the line X-X′;

FIG. 3 is a sectional view showing, in an enlarging manner, an exampleof a structure that can be employed in the display shown in FIG. 1;

FIG. 4 is a sectional view showing, in an enlarging manner, anotherexample of a structure that can be employed in the display shown in FIG.1;

FIG. 5 is a perspective view showing, in enlarging manner, an example ofa structure that can be employed in the relief-structured regionaccording to the present invention;

FIG. 6 is a conceptional view showing a state where a display accordingto an embodiment of the present invention, which has a printed layer anda relief structure-forming layer perceived as almost the same color, isobserved under a normal illumination condition;

FIG. 7 is a conceptional view showing a state where the displayaccording to the embodiment of the present invention, which has theprinted layer and the relief structure-forming layer perceived as almostthe same color, is observed under a specific illumination condition;

FIG. 8 is a conceptional view showing a state where a display accordingto an embodiment of the present invention, which has a printed layerformed from a functional ink and a relief structure-forming layer, isobserved under the normal illumination condition;

FIG. 9 is a conceptional view showing a state where the displayaccording to the embodiment of the present invention, which has aprinted layer formed from the functional ink and the reliefstructure-forming layer, is observed under the specific illuminationcondition;

FIG. 10 is a conceptional view showing a state where a display accordingto an embodiment of the present invention, which has a printed layerforming a latent image pattern and a relief structure-forming layer, isobserved under the normal illumination condition;

FIG. 11 is a conceptional view showing a state where the displayaccording to the embodiment of the present invention, which has theprinted layer forming the latent image pattern and the reliefstructure-forming layer, is observed under the specific illuminationcondition;

FIG. 12 is an enlarged sectional view of a relief-structure-forminglayer (relief-structured region) including recessed or protrudingportions having a truncated shape;

FIG. 13 is a plan view schematically showing an example of anarrangement pattern of recessed or protruding portions or both of themthat can be employed in the relief structure-forming layer(relief-structured region);

FIG. 14 is a plan view schematically showing another example of anarrangement pattern of recessed or protruding portions or both of themthat can be employed in the relief structure-forming layer(relief-structured region); and

FIG. 15 is an illustration schematically showing an example of aninformation-printed matter (IC card) including the display according tothe embodiment of the present invention.

NOTES ON REFERENCE SYMBOLS

-   -   1 . . . display, 2 . . . relief structure-forming layer, 3 . . .        light-reflecting layer, 4 . . . printed layer, 5 . . .        substrate, 6 . . . relief-structured region, 7 . . . adhesive        layer, 8 . . . protruding portion, 9 . . . rectangular region,        10 . . . concealed image, 11 . . . peripheral portion of        concealed image, 12 . . . flat surface, 13 . . . recessed or        protruding portion, 20 . . . IC, 30 . . . second printed layer,        50 . . . printed matter substrate, 100 . . . information-printed        matter.

1-13. (canceled)
 14. A display comprising: a substrate with alight-transmitting property, said substrate having a first surface and asecond surface opposite to each other; a relief structure-forming layerhaving a first surface and a second surface opposite to each other anddisposed relative to the substrate such that the first surface of therelief structure-forming layer faces the first surface of the substrate,the second surface of the relief structure-forming layer including arelief-structured region, the relief-structured region includingrecessed or protruding portions arranged with constant periodicity infirst and second directions crossing each other; a light-reflectinglayer disposed at least partially on the second surface of the reliefstructure-forming layer and at least partially covering therelief-structured region; and a printed layer disposed at one of firstto third positions, the first position being at a side of the substrateopposite the relief structure-forming layer, the second position beingbetween the relief structure-forming layer and the light-reflectinglayer, and the third position being at a side of the light-reflectinglayer opposite the relief structure-forming layer, wherein acenter-to-center distance of the recessed or protruding portions and aheight or depth of the recessed or protruding portions are configuredsuch that the display displays black or dark gray at a positioncorresponding to a portion of the relief-structured region covered withthe light-reflecting layer when the display is observed perpendicularlywhile irradiating the display with light in a direction perpendicular tothe first surface of the substrate and such that the display displayscolors of diffracted light when irradiated with light at an acute angle,wherein the center-to-center distance of the recessed or protrudingportions is 400 nm or less, and wherein the height or depth of therecessed or protruding portions is 200 nm or more and 600 nm or less.15. The display according to claim 14, wherein at least a part of theprinted layer is provided with a latent image pattern that causes achange of a displayed image according to an observation angle.
 16. Thedisplay according to claim 14, wherein a surface area of the singlerecessed or protruding portion is equal to or greater than 1.5 times anoccupied area necessary for placing the single recessed or protrudingportion on the surface of the relief structure-forming layer.
 17. Thedisplay according to claim 14, wherein a section of the recessed orprotruding portion has a tapered shape.
 18. The display according toclaim 14, wherein the recessed of protruding portion has one oftruncated cone shape, truncated prism shape and truncated elliptic coneshape, a truncated top of the recessed or protruding portion has a flatsurface parallel with the surface of the substrate, and a width of theflat surface is 90 nm or less.
 19. The display according to claim 14,wherein the recessed portions or protruding portion are arranged in amatrix form at a predetermined center-to-center distance.
 20. Thedisplay according to claim 14, wherein the recessed or protrudingportions are arranged in a honeycomb form at a predeterminedcenter-to-center distance.
 21. The display according to claim 14,wherein the center-to-center distance of the recessed or protrudingportions is 250 nm or more and 300 nm or less.
 22. An informationprinted matter comprising: the display according to claim 14; and aprinted matter substrate supporting the display.